Method and apparatus for producing optical coatings



Dec. 5, 1950 o. VAN LEER ETAT. 2,532,971 METHOD ANO APPARATUS FOR PRODUOING OPTICAL cOATTNGs Filed April 12, 1947 2 Sheets-Sheet 1 TTOENEV Dec. 5, 1950 o. VAN LEER ETAL METHOD AND APPARATUS FORY PRonucING OPTICAL coA'rINGs Filed April 12, 1947 2 Sheets-Sheet 2 `INVENTORS OSC'HIQ VHN LEE@ MO'Qe/S F7. ZOUK, J2.

Patented Dec. 5, 1950 METHOD AND AEPARATUS FOR PRDUCIN G OPTICAL COATINGS Oscar van Leer, lujunga, and Morris A. Zook, Jr.,

Rosemead, Calif., assignors, by mesne assignments, to Pacific Universal Products Corporation, Pasadena, Calif., a corporation of California Application April 12, 1947, Serial No. 741,110

3 Claims.

This invention relates generally to the art of thermal evaporative coating in vacuum and more particularly to an improved process and apparatus for forming transparent films of improved quality on optical surfaces for the purpose of modifying their light reflectivity and transmission characteristics.

It is now well known that the reflectivity and transmission characteristics of an optical element can be modified by the deposition on its optical surface of a transparent layer of a suitable substance having a thickness in the order of a Wave length of light and having a refractive index different from that of the optical element material. Where the desired effect is that of minimizing reflectivity and increasing the transmission for a given Wave length of light it has been shown by John Strong (Optical Society of America V. 26, P. 73, January 1936), Cartwright and Turner U. S. Patent Re. 22,076 and others, that Where a single film thickness is employed, it should have a thickness of one-quarter of the Wave length for which the minimum reflection is desired and a refractive index equal to the geometric mean between that of the optical element upon which the film is formed and that of the surrounding medium in contact with the exposed surface of the nlm.

No material h-as been found which exactly meets all the requirements under all conditions for an ideal coating material for glass, optical elements to be employed in contact with the atmosphere, particularly for reduction of surface renection, for the reason that none has been found With a refractive index sufficiently low and at the same time possessing the required transparency and the desired mechanical qualities. Materials which havel been found to most nearly meet the desired require-ments are various metallic halid'es such as the fluorides of sodium, lithium, calcium and magnesium and certain mixtures thereof, but coatings of these materials have in general had the disadvantage of insufoient durability. Coatings of these materials have heretofore exhibited characteristic's of insufhcient tenacity and hardness and excessive susceptibility to moisture and other detrimental atmospheric effects which have unsuited them for use Where such coatings must be exposed to the atmosphere or be handled and frequently cleaned and otherwise subjected to abrasion as,v for example, in connection With spectacle lenses.

Many processes have been suggested for improving the physical characteristics of such coatings. For exam-ple Cartwright Re. 22,076 suggests the use of a deposited, thin, protective overlayer of quartz or Zircon; Lyon 2,398,382 discloses baking the layer of metallic fluoride during and after deposition to increase its ruggedness, and Richards 2,391,595 describes an involved process including the employment of a plurality of superimposed different layers of such materials subjected to a prolonged electronic bombardment.

While some of those suggested treatments such as the baking process appear to be effective in somewhat improving the hardness and durability of these deposited films, they do not alone succeed in effecting the degree of improvement in film quality desired nor do they appear to recognize or eliminate a probable major cause of the initial lack of durability of such films particularly those deposited upon double optical surfaces such as those of lenses and spectacle glasses.

It is therefore an object of this invention to provide an improved method and means for coating objects, particularly the optical surfaces of light transmitting or reflecting bodies such as flats, prisms, lenses and reflectors.

It is a further object of this invention to provide a process and' means for coating optical surfaces with coatings of improved hardness, durability, tenacity and general resistance to deterioration.

It is a particular object of 'this invention to provide a method and apparatus for, in effect, simultaneously coating both sides of an optical element from a single source of coating material vapors.

It is a still further object of this invention to provide a method and apparatus for forming improved optical coatings simultaneously on oppcsitely facing surfaces of optical elements from a single source of coating materials.

It has been found that where an optical element such as for example, a lens having opposite optical surfaces to be coated, is placed in a vacuum chamber and coated first on one surface and then turned over in the chamber and a second coating formed on the other surface in a manner such as, for example, that shown and described in McLeod 2,260,471 or Dimmick 2,498,614, and others, certain effects detrimental to the quality of the resulting coatings occur. The second coating formed on the surface initially facing away from the coating vapor source is found to be materially inferior to therflrst coating thus formed on the surface initially facing the coating vapor source, and the coating first formed is also found to be inferior to that which is initially formed thereon prior to the reversal of the position of the element for deposition of the second coating.

The reasons for the before-mentioned results are not entirely understood but it is believed that possibly one or both of the following contributing detrimental eects occur:

The first detrimental eifect may be related to the well known fact that in the process of evaporative coating in high vacuum the major portion of the vapors appear to radiate in straight lines from the source point of emission to the target surface being coated. It is also recognized that a minor portion of the emitted vapors do not reach the target area by a direct free path but become diffused by collision with residual gas molecules in the evacuated chamber and that a certain portion of such diffuse vapors reach the target surface and other surfaces of the obiect by an indirect path to form a so-called inadvertent or secondary deposit. This effect appears particularly noticeable upon the surface of the obiect. opposite to that facing the vapor source, where the entire coating, if necessarily consists of only the inadvertent or secondary deposit. When the optical element is then turned after completion of the coating of the first surface to expose the other surface (carrying the previously deposited indirect or inadvertent deposit) to the direct vapors, the coating formed on the surface is then apparently deposited upon the previously formed inadvertent coating. with the result that the bond between the resul-ting coating and the optical surface appears to be weak and the coatingr as a whole lacks hardness and durability.

The second of the before-mentioned effects may possibly be due to the expulsion of gases or other constituents from the body of the optical element with their absorption or accumulation on or resultant alteration of the characteristics of the optical surface in a manner detrimental to the bond or duality of the subseouently deposited coating. This latter effect appears to be most pronounced on the surface initially facing away from or shielded from the direct vapor source, possibly for the reason that suicient time is permitted during the deposition of the first coating to allow the accumulation of such effect in considerable degree on that surface before any direct deposit is initiated. That this latter effect probably occurs, at least to an appreciable extent, appears to be supported by the discovery that shielding or masking-off of the surface opposite to that upon which direct deposition is initially performed. to thereby prevent any inadvertent or indirect deposit thereon, does not entirely overcome or eliminate this said latter detrimental effect.

Heretofore, for the reasons hereinbefore mentioned. it has been necessary before the object or optical element upon which the first coating had been completed could be reversed in position in the vacuum chamber for deposition of a second coating on the opposite side. to break the vacuum in the chamber, remove the object or optical element therefrom and subject the surface upon which the second coating was to be deposited to a suitable cleaning process for removing the inadvertent deposit or for eliminating the other before-mentioned effects and then replace the thus cleaned element in the chamber with the cleaned Surface facing the source of vapors and the coating process then continued. The resultant inefliciency of the latter process is obvious, and furthermore, during this later depositing step unless other means are provided for preventing it, an

d undesirable inadvertent coating is formed over the previously deposited layer.

It has been discovered that if the object to be coated on several different surfaces is continuously shifted in position, as, for example, in the case where the object is to be coated on both sides is a lens and it is continuously turned over or rotated so as to alternately expose the opposite sides or opposite optical surfaces thereof in moderately rapid succession, the inadvertent deposit or other detrimental effects are prevented from accumulating in quantity on any one side of the lens and are apparently, in effect, sufficiently uniformly intermixed with the direct coating to reduce greatly if not substantially to eliminate all detrimental effects.

It has been further discovered that direct eX- posure of the surface undergoing direct coating to radiant heat continuously or intermittently during the coating deposition time interval is advantageous in minimizing any detrimental effect of the intermixed inadvertent deposit and in hardening and forming a more durable and tenacious coating layer.

With the foregoing objects and discoveries in view, this invention resides generally in a method of and an apparatus for, substantially simultaneously coating opposite or different sides of an element such as the opposite optical surfaces of an optical element, from a single source of vapors in vacuum wherein the said element is moved or rotated to expose alternately, repeatedly and in relatively rapid succession the separate or opposite surfaces to be coated to the direct vapors from the vapor source.- 'Ihe invention also includes the direct exposure of the deposited surface layers to radiant heating.

The foregoing and other objects, advantages and features of novelty will be evidenced hereinafter.

In the drawings which show by way of illustration a preferred embodiment of the invention and in which like reference characters designate the same or similar parte throughout the several views:

Figure l is a sectional elevation of the general assembly of the apparatus.

Figure 2 is a cross-sectional view taken on line 2-2 of Figure 1 showing the arrangement of the heating element.

Figure 3 is a fragmentary cross-sectional view taken on line 3 3 of Figure l, showing a number of the holders for elements to be coated.

l Figure 4 is a fragmentary detailed view of one of the element holders of Figure 3, and

Figure 5 is a cross-sectional view taken on line 5-5 of Figure 4.

Referring now primarily to Figure '1, a rigid metal base plate Ill is provided, upon which the open end of a bell jar I! is adapted to seat and be closed thereby to form a vacuum chamber I2. A channel shaped gasket I3 made of suitable resilient material such as rubber or neoprene is carried on the beaded edge of the mouth of the bell jar II and serves both as a cushion support and a gas tight sealing means between the bell jar I I and the base lll. An encircling metal band le is xed in clamping engagement about the mid section of the bell jar II. A pair` of upright, supporting members l5 and i6 extend upwardly from points of connection at diametrically opposite sides of the band i4 and make connection with the respective outer ends I1 and I8 of a horizontally positioned supporting yoke member 20. The yoke member 20 is provided on its upper surrace with a paircf spacede eyes; 2&2? andzz to; which areattached a. pair ci: survol-'ting` ropes or cablesV Z411 andi 25. The ropesor cables` 24" and 2.55l are adapted to:A pass over` suitable; pulleys to; a; counterw.eightu, (not. sl'iownlL A second metalv band; 21k is. clampedaboutthe` lower end portion` ottheabell jar Hl and:tl'flis.:band"l carries s. a. pairV ot guide.` inellfllvers.;l Z9; and 320i. The; guide members 29 and 3.`0;I are.provided:Witlrguide:v openings.- 3 t and adaptedY to` make. Sliding. lltrespectively upon. vertical-lf guide: rods; 35 and 36 which are attached; 'at-their lbwer'ends asf shown: at13'lf' andi 38.' to: thegbaseiplate; |10.. The; bell jar: i-Iif isf` thus: adapted to.. berv guid'edlv;A raisedf and: lowered with respect; to. the base; plate, Illf andi suspended at;l convenient: distances. thereabcve through the.; action. oi* the; suspending cables; 24' and: 25; and the before-mentioned. countervreght.. Apipe 4|); makes flanged* connection; asrshowrr. at

4=| andi 421 under an: opening t3` which, extends.-

through the-centrar portion of thebase; pla-te l0. The-piped!) is: adapted to make. connection Withf a suitabley vacuum pump (notshown). by means;v or which? the chamber t2; formedt within; the` bell jap l't' when. it: is sealedl against; the base:-I plate; l0 as shown in Figure 1, may be suitably evacu-l ated?.

Supported within the opening.` 4&- upon.- the; flange 4'41 of*A the. pipe 40. is' a smally metal table 45" and` in turn supported; upon, the. top o the; ..1

table 451is'acrucibleforboat4$ adapted to contain a supply; of' a suitable coating material 41..

A spiral, resistance heating v element; on filament` 5i)` is providedv for heating the material 41 in the.`

crucibleAS, by radiation, to a-.vaporizingf {animera-I4 12;.'

ture; The filament 50' issuppultedbyrandamakes electrica-l' connection at; its opposite; ends.` with a pair of supporting conductor arms 5|; and 52. which in turn are supported byu and mairey elec tri'cal connection with a pair` of spaced terminals: 5.3. and 54; which extend:A througlzi.` the base plate.4

HI through suital'lle air-tighty lead-in` insulators as: shown at 56" and` 51'. The' terminals. 53.' and:A 5.4"- make connection on, the outsid'e ot the chamber by way off suitable conductorsrasf. shown at. 5&1 and 59: with a source ot electric.r current:A (notshownla Secured. tol the'base plate; l0?, Within the corrtactr area ofv the lower; edge or the;- mouth: ofA the;v bell jar L'If. as. shown at 5th and El?, are; a.. pair of: vertical standardslrand B4 whichlmake supporte ing` connection attheir upper. endsV withv a ring.; member 6.5. Aplurality' of. frame members 6.1: as best shown in-,Figure extend, radially betweencircumierentiallyspaced points; of attachments to: the. ring; member 651v a central' hub Gitte; tor-m a spider member` tor; sil-porting. the heating?,- element` as more` fully'- describedi hereinafter...

A bushing 69 is.threadeclly,A connectedfas-shown. at 'infy through the: hub 6% and a.. shalt-..12f extends-.r

through the. bushing 63: and is. rotatably: sup.-

ported therein as more. fully described; herein-- atten,

Each of the radial' members,l 6ft of' the heaterA element spider isf provided' with an plurality4 or spaced,v standfoi insulators. "15.2 attachedii to the lower surface thereon. tov which is attached.. and? about which. is:V wound',v in. spiral: arrangements.. a. suitable resistanceewire heating element; '1;51.. The opposite ends- 11; andd 118; of thev wire heatf ingyelcment '1;6 make connection through suitable conductors diagrammatically shownl at.. 1;!! amb Bil respectively, to the;beforementioned` terminal 53 and another; terminal; 8A2f which, eater-ida through the base plate: l0; through asuitable: air-tight lead-iui insulator arrangement asl-shawn innerA surface thereof..

ment supporting mechanism or structurel S is provided', the. assembly ofwhichis adapted tobe detachably'supported asa whole from the heater ring ii5fby means.v ofa plurality of vhook membersl as. shown atl 90. The before-mentioned element supporting structure S comprises an outer ring 9.l-', an innergear box o1'A housing 93` having a re- :t movable cover 9.# and-1a plurality of radial, inter-l.

connecting members 92.

A ring gear 95 housed Within the gear box 93", is fixed to a central shaft Sii which is, in turn, rotatably supported adjacent its upper end' in an adjustable bushing @it andz at its lower end in an inwardly extending bearing Si?. carriedvby the before-mentioned? cover ille'. The upward end" of shaft 95 is provided with a cross pin itil; which,k when the apparatus. is assembled as show-n in Figure 1', ts into and makes rotational coupling engagement with a pairoffdiametrally' opposite slotsK in a coupling member mi.: formed at the lower portion of" the before-mentioned shaft T2. A; plurality of.- sloping, radiallydirected shafts extend outwardly, as shown'. aat," through suitable bearing openings inthe sides of thegear box 93?, to suitable outer-enti bearing members* carried bythe ring al: inner ends off the shafts', as shown at: H15. which extend into the gearbox 93, eachcarryvxed thereto a pinion, as shown at IEW; which` make meshing engagement with the before-n'ientioned;v ring gearY` t5.

The; radial shaftsv M35i have formed' integral therewith, suitable; means* for holding objectsto bel coated, which Way of example in the present case, areadanted to retain discshapedoptical elements orlenses as shownA at i it' in Figure 4. Each. such holder' comprises an outer ring shaped frame ilfl carryingA at one side a E. pair of fixed', inwardly projecting lugs as shown aty H2 and at the diametricalfy opposite sidey a similar pair or.v inwardly projecting, mor/able lugs Irlf3; attached to the outer; surface of the rings IHr byineans of az curved leaf. spring Hd.

A circular frame H5. is adapted* to be detachably supported; within: the ring IM betr-,reen the before-mentioned lugsv H2x and M3'. The frame itl-'5 isY provided with a curved spring li'i. attached at itsA mid-point as Shown at lil to the The curved spring lit carries at; its oppositev outer ends a pairof VEL-shaped jaw rmembersa H@ and H9 adapted to make gripping engagement over the edge; of.' the optical elem-ent or lens l Mi'. Diametrically opposite the pointof` attaclimenty Hz? is an angle clip memberv 5:2 il attachedlto, the frame l I5. The ang-leclip EZB is provided with aradially directed slot 121.., A v-shapedr. jawf member i222 is attached tothe outer end of. and is slidably supportedi from they upper surface cfg the clip i291 by; aslide plate. 23. A bolt having a. thumbscrew asrshown at 24" passes through a holeI the slide plate. L25; and through, the clip slot [2a and serves to.` supply means for r adjusting; the. radial posi'- tion of the jaw member |22: to. suit the.y size of the optical element to bel supported: therein such as that-:shown at Het The javr lement. 22, as in thev case; or elements;V tigt; and` lle, is adapted; to.: lit. osier the; edge of; an. optical ele- The shaft I2 having the before-described coupling member |Q| at its lower end, as shown in Figure l, extends upwardly through and is rotatably supported by the bushing 69 and is fixed in a hub |25 which is in turn attached to the center of an armature bar or rotor member 26 made of suitable ferro-magnetic material. The outer ends of the armature bar or rotor |25 are shaped or curved to conform with the curved inner surface of the dome of the bell jar and are spaced in close proximity thereto, permitting just suiiicient clearance for rotation about the axis of the shaft 12.

A pair of field electromagnets as shown at |29 and i3() are adapted to be rotated coaxially with shaft '52 and in close proximity to the outer surface of the dome of the bell jar upon a field yoke member |3|. The yoke member |3| is rotatably supported at its center section by a shaft 32 which is in turn rotatably journaled within a bearing |33 rextending through and fixed to the central portion of the before-described supporting yoke 2l).

A gear |35 is keyed to the field shaft 32 and is adapted to be driven by a pinion lt@ and the shaft of an electric motor |31.

The eld shaft |552 carries a pair of slip rings |38 and |35 insulated from one another and from the shaft |32 by a suitable insulating collar Ulu. rhe slip rings |38 and |39 are connected electrically to the series connected field electromagnets |2Q and |39 by means of suitable conductors diagrammatically shown at IM, |52 and |43. A pair of brushes M5 and Mii make sliding contact with the outer surfaces of the slip rings and are supported by means of a standard |43 attached to the lower surface of the yoke 2G. The brushes M5 and M6 are connected through conductors |50 and l5! to a suitable source of electric current (not shown) for energizing the field electromagnets |29 and |39.

The operation of the apparatus is as follows:

Assuming the apparatus to be assembled as illustrated in Figure 1 the bell jar i l is iirst elevated and suspended a suitable distance above the base plate i!! by means of the supporting members |5 and I6, the yoke member 2l! and cables 24 and 25, said elevation being suflicient to expose the optical element supporting structure iS. The structure S may then be removed by reaching under the open end of the bell jar and raising the structure S slightly and swinging the hook members S@ outward out of engagement with the ring 9|, after which the element supporting structure S is free to be lowered and unccupled from the shaft l2 and coupling ISS. After removal of the element supporting structure S the clip frames H5 may be removed from the clip holder rings i|| and each clip holder ring loaded with an optical element to be coated such as, for example, the double convex lens illustrated at ll. After the clip frames have been loaded and replaced in the clip frame holders lll, the whole element supporting mechanism S is reinstalled in the apparatus illustrated in Figure l by first inserting the upper end of the shaft |61 and coupling pin |08 in to the coupling and then swinging the hook members 9 inward into supporting engagement with the ring 9|.

Next the crucible 48 may be lled, as shown at 47, with a suitable material from which the evaporative coating is to be formed and the Crucible placed under the heating element 55. Next the bell jar l is lowered bringing the bottom end of the bell jar and the gasket I3 into sealing contact with the upper surface of the base plate Ill. At this point evacuation of the chamber |2 through the connection 4|) by means of a suitable vacuum pump (not shown) may be commenced and shortly thereafter the heating element "I6 may be energized by applying a suitable current to the connections 58 and 85. At the same time the field electromagnets |29 and |39 are venergized and the motor |31 may be started to cause the arm |3| and the eld electromagnets |23 and |30 to rotate. Due to the magnetic attraction between the magnets |29 and I3@ and the outer end of the armature bar |26 inside the bell jar, rotation of corresponding speed is imparted to the armature shaft 12 which, as hereinbefore described, is coupled by means of a pin connection lef! and coupling l0! to the shaft and rotation is thereby transmitted through the ring gear to the pinions Ell and thence to the shafts |05. The lens holders carrying the optical elements il!) are thus caused to rotate about the axis of the shafts |95, thereby alternately exposing opposite surfaces of the optical element to the direct heat radiated from the heating element l5 thereabove.

When the vacuum has attained a suitable value and the temperature of the optical elements to be coated has been brought up to approximately 450 F. the heating element 59 may be energized by connecting the conductors 58 and 59 to a suitable source of electric current. The heating element 5|] is thereby heated to incandescence and by the radiation therefrom the coating material 47 raised to its vaporization temperature.

The vapor issuing from the heated material 41 impinges on all of the surfaces in its direct path thus coating the exposed, hot surfaces of the optical elements |00 as they rotate with the holders As hereinbefore mentioned, it has been found that a minor portion of the vapors being emitted from the heated source material il? undergoes a certain amount of diffusion by reason of impacts with residual air molecules in the evacuated chamber and a small percentage of the vapors thus apparently reach the surfaces of the optical elements IQ by indirect paths and a small percentage of the coating may be formed in this way on the surface of the optical elements which are facing away from the source 431 during rotation. However, as contrasted with the usual practice of holding the elements stationary while complete deposition takes place on the surface facing the source material and at the same time a substantial layer of secondary material is deposited or certain other detrimental effects occur on the surface of the lens facing away from the source, here the optical surfaces are constantly rotated, as before described, thus preventing any material accumulation of secondary coating material on the surfaces and minimizing any other detrimental modification of the surface characteristics. That portion of the coating material which does reach surfaces of the optical elements indirectly is thereby apparently progressively intermixed with or modified in form by the greater percentage of the materials which reach the surfaces directly and direct deposition is initiated on all surfaces before any other detrimental alterations of the surfaces upon which the coating is to be formed can take place.

The heating of the optical element, the evacuation of the chamber and vaporization of the coating material are simultaneously continued until a suitable layer of the desired thickness of the coating material has been deposited on the several surfaces of the optical element. Upon completion of the coating the heating element 50 is disconnected from the current source and the heating filament 7B may also be disconnected from its current source at the same time or a suitable time interval thereafter. The optical elements are preferably first permitted to cool somewhat while maintaining the vacuum and then the vacuum is slowly reduced.

After completion of the coating processes as hereinbefore described and after the vacuum in the chamber I2 has been reduced to atmospheric pressure the bell jar l l may then be elevated from the base l and the element supporting mechanism S removed, after which the clip frames H may be removed from the clip frame holders l l l and the optical elements H0 removed from the clips.

Suitable dimensions and operating characteristics under which apparatus of the type hereinbefore described has been successfully operated are as follows: The heating filament 50 may be made of No. 020 tungsten wire and wound in a spiral of four turns having outer diameter of inch and an approximate average diameter of T55 inch. Suflicient current is supplied to the filament 50 to heat it to a brilliant incandescence. A current of from 21.0 to 24.4 amperes at from 13.6 to 17.7 volts respectively has been found satisfactory. The heating filament 50 may be placed approximately 1/8 to 1A inch above the upper surface of the material fil, in the case of magnesium fluoride, which is to be heated and evaporated.

The optical element supporting structure S may be located above the crucible 40 in such a position as to place the surfaces of the optical elements H0 in place in the clip frame support at a distance of approximately il inches from the vapor source.

The heater element 'l5 may be placed above the optical element supporting apparatus in such a position that the heating element wires are approximately 2 inches above the optical elements on the average during their rotation. The heating element 75 may be made of No. 040 nichrome resistance wire and of such a length as to consume approximately 15 amperes at 100 volts.

In operation the heating element 76 is controlled so as tc heat the optical elements being coated to a temperature of about 450 F. and the optical elements are rotated at approximately 50 revolutions per minute during the heating and coating processes. The vacuum in chamber I2 is preferably maintained between approximately 4 10-4 to 5 106 millimeters of mercury during the depositing stage. Ordinarily the source material for vapors, shown at 47, comprises magnesiurn fluoride but the process and apparatus of this invention may be advantageously employed similarly for other coating materials such as for example various other metallic fluorides such as those of sodium, lithium and calcium, also cyrolite (sodium-aluminium fluoride), zinc sulphide, lead sulphide and quartz. Metals such as silver, aluminium, copper and chromium may also be deposited.

The progress of film deposition on an optical surface in accordance with this invention may be determined by observing the color of the light reflected therefrom as is now Well known in this art.

It is to be understood that the foregoing is illustrative of but one apparatus and that the invention is not limited thereby but may include various modifications and changes made by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

We claim:

l. A process for evaporative coating of objc't surfaces in vacuum comprising: supporting on a substantially horizontal axis an object to be coated in an evacuated chamber; evaporating coating material in said evacuated chamber at a source point below said object; continuously rotating said object about said axis at about 50 P. M. in said chamber during said evaporation to expose directly different portions of the surfaces of said object alternately to said vapors emanating from said source below and to radiant heat from a source located above said object, said radiant heat maintaining said object at a temperature of approximately 450 F.

2. Apparatus for evaporative coating of object surfaces in vacuum comprising: a base member; a bell type container open at its bottom and forming, when said open end is in sealed engagement with said base member, a chamber adapted to be evacuated; means for emitting coating vapors in the lower portion of said chamber adjacent said base member; an upright standard on said base member and extending into the upper portion of said container; an element-supporting assembly detachably supported by and positioned adjacent the upper end of said standard, said assembly including therein a plurality of holders for objects to be coated rotatably journaled thereto and a first shaft rotatably mounted in said assembly and coupled to said holders for rotation thereof; a second shaft rotatably supported by said standard; a detachable coupling between said first and second shafts, said element-supporting assembly being thereby adapted to be detached from said standard and removed from said chamber when said container is elevated from said bodies; an armature coupled to said second shaft and positioned for rotation with said shaft within and adjacent the upper end of said container; a frame fixed to the exterior of said container; power means mounted upon said frame; magnetic means mounted upon said frame and rotatable by said power means adjacent the upper exterior surface of said container in magnetic coupling relationship with said armature; and means for elevating said frame, power means and container as a unit from contact with said base member.

3. Apparatus according to claim 2- and a heating coil fixed to the upper endV portion of said standard, above said detachable element-supporting assembly.

OSCAR VAN LEER. MORRIS A. ZOOK, JR.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 2,260,471 McLeod Oct. 28, 1941 2,351,537 Osterberg June 13, 1944 2,383,470 Morgan Aug. 28, 1945 2,398,382 Lyon Apr. 16, 1946 2,408,614 Dimmick Oct. 1, 1946 2,414,400 Colbert Jan. 14, 1947 

